Test Strips for Cancer Detection Get Upgraded with Nanoparticle Bling

Detecting cancer could be as easy as a home pregnancy test. Platinum-coated gold nanoparticles could make cheap and simple test strip detection a reality.

The most common test strip people might think of for diagnosis is a home pregnancy test. Pregnant women have steadily increasing levels of the biomarker human chorionic gonadotropin (hCG), which is easily detectable in urine and a thin, colorful strip of antibodies will appear when hCG is present.

However, there's a lot more hCG in pee than there is of cancer biomarkers in blood. Identifying minute concentrations is the greatest challenge of test strips that have been developed to detect everything from cancer to infectious diseases to heart problems. The actual stripe on the paper simply isn't sensitive enough to change color for a human eye to easily see it at concentrations that make a life-changing difference.

Some nanoparticle bling could change that. And it would not greatly impact the cost of current test strips according to new research led by Xiaohu Xia, an assistant professor of chemistry at Michigan Technological University. The research was published recently in Nano Letters (DOI: 10.1021/acs.nanolett.7b02385).

By coating nanoparticles in thin layers of platinum, only a few atoms thick, Xia's team was able to increase the sensitivity of test strips that detect prostate-specific antigen (PSA).

Gold Nanoparticles with Platinum Skins

Gold nanoparticles have been used widely for decades for in vitro diagnostics to make medical care and treatment decisions quicker and easier for physicians and patients. What is new with Xia's research is adding a dual function to the nanoparticle by decorating each tiny sphere in a thin skin of platinum.

Doing so makes it easier for the naked eye to observe changes on the test strip. It also increases the accuracy and provides quantifiable results for extremely low concentrations of key biomarkers, which are measured in picograms per milliliter. In Xia’s study, they focused on prostate-specific antigen (PSA), looking for signals of mere trillionths of a gram in a single drop of blood.

"We require the detection to be very sensitive," Xia says, explaining that platinum is a great catalyst and a little goes a long way to boost the chemical reaction that causes a test strip stripe to show up. "Gold nanoparticles are a distinct red color and as long as the platinum is ultrathin, the red of the gold nanoparticles will show through."

Xia’s team took that improvement a step further: they created a low-sensitivity mode (color from gold nanoparticle cores) and a high-sensitivity mode (color produced by platinum skins through catalysis) to detect PSA. As the photo below shows, the high-sensitivity mode greatly improves test strip visibility; the low-sensitivity mode is on par with commercially available test strips.

Gold nanoparticles appear red on test strips; the high-sensitivity mode developed by Xia's team is much darker on the test strip and shows a two-magnitude increase in sensitivity.

Detecting Disease

What’s more is that Xia estimates the thin platinum skin will not significantly increase the cost of current gold nanoparticle test strips on the market and the design is compatible with detecting other kinds of cancer biomarkers.

“A key component in the test strip is the antibodies, which are unique to each cancer biomarker, and are commercially available,” he says. “We can easily replace the antibody, so this is a general detection platform.”

The next step Xia says is verifying the application for other cancer biomarkers and even experimenting with applications for infectious diseases.

“The advantage of this technology is simple,” he says. “Point-of-care devices mean people can buy them and do diagnosis on their own; in a clinic, this is a cheap and quick technique that also improves diagnosis and therefore treatment.”

All it took was a bit of decorating. Adding some new platinum bling to old-school gold nanoparticles will help push improved test strip technology out of labs into clinics and homes.

Michigan Technological University is a public research university, home to more than 7,000 students from 60 countries around the world. Founded in 1885, the University offers more than 120 undergraduate and graduate degree programs in science and technology, forestry, business and economics, health professions, humanities, mathematics, and social sciences. Our beautiful campus in Michigan’s Upper Peninsula overlooks the Keweenaw Waterway and is just a few miles from Lake Superior.

Grants and Funding

This work was supported in part by the startup funds from Michigan Technological University and a National Science Foundation (NSF) Career Award (CHE-1651307). Part of the electron microscopy work at Brookhaven National Laboratory was supported by the U.S. Department of Energy, Basic Energy Sciences, Division of Materials Science and Engineering, under Contract No. DE-SC0012704.

About the Author

Allison Mills

A through and through geek, Allison writes university research stories. She studied geoscience as an undergrad at Northland College before getting a master's in environmental science and natural resource journalism at the University of Montana. She moonlights as a dance instructor, radio fiend, and occasional rock licker.